Effect of confining stress and lateral boundary conditions on the drained instability response of sand: a DEM based assessment across the length scales
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引用次数: 0
Abstract
Instabilities in geomaterials significantly influence its strength mobilization and often act as a precursor to failure in geotechnical structures. Such instabilities in a granular assembly can vary drastically from localized to a diffused mode owing to the changes in density state, i.e. from a dense to a loose one. The present study elucidates the effect of confining stress and lateral boundary conditions on the mechanisms associated with these instability modes through particle-scale observations and relates it to the macro-scale shearing response of the specimen with a particular focus on the density state. In this regard, 2D DEM simulations of drained biaxial test have been carried out for the dense and loose sand specimens at different initial confining stress, and under both flexible and rigid lateral boundary conditions. Analysis of force chain network indicates that the formation of higher number of elongated strong force chains increases the susceptibility of local buckling of strong force chain in dense specimen, resulting emergence of shear bands. Conversely, buckling of a large number of strong force chains of smaller lengths, distributed across the loose specimen, causes diffused instability as can be perceived from the scattered large particle rotation and relative displacement field. Assessment on fabric anisotropy reveals that, with increasing confinement, the weak force chain network provides enhanced lateral support to the strong force chain network and retards the force chain buckling process, resulting in a reduction in the shear band thickness and delayed peaks in the macro-scale strength response. Shear band thickness and inclinations are noticed to be higher for rigid lateral boundaries, which due to constraint kinematics leads to a constant shear band inclination regardless of the level of confinement.
期刊介绍:
Although many phenomena observed in granular materials are still not yet fully understood, important contributions have been made to further our understanding using modern tools from statistical mechanics, micro-mechanics, and computational science.
These modern tools apply to disordered systems, phase transitions, instabilities or intermittent behavior and the performance of discrete particle simulations.
>> Until now, however, many of these results were only to be found scattered throughout the literature. Physicists are often unaware of the theories and results published by engineers or other fields - and vice versa.
The journal Granular Matter thus serves as an interdisciplinary platform of communication among researchers of various disciplines who are involved in the basic research on granular media. It helps to establish a common language and gather articles under one single roof that up to now have been spread over many journals in a variety of fields. Notwithstanding, highly applied or technical work is beyond the scope of this journal.
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